SYNCHRONOUS MOTORS
The construction of the
synchronous motors is essentially the same as the construction of the
salientpole alternator. In fact, such an alternator may be run as an ac motor.
It is similar to the drawing in figure (1). Synchronous motors have the
characteristic of constant speed between no load and full load. They are
capable of correcting the low power factor of an inductive load when they are
operated under certain conditions. They are often used to drive dc generators.
Synchronous motors are designed in sizes up to thousands of horsepower. They
may be designed as either single-phase or multiphase machines. The discussion
that follows is based on a three-phase design.
fig.(1) |
To understand how the
synchronous motor works, assume that the application of three-phase ac power to
the stator causes a rotating magnetic field to be set up around the rotor. The
rotor is energized with dc (it acts like a bar magnet). The strong rotating
magnetic field attracts the strong rotor field activated by the dc. This
results in a strong turning force on the rotor shaft. The rotor is therefore
able to turn a load as it rotates in step with the rotating magnetic field. It
works this way once it’s started. However, one of the disadvantages of a
synchronous motor is that it cannot be started from a standstill by applying
three-phase ac power to the stator. When ac is applied to the stator, a
high-speed rotating magnetic field appears immediately. This rotating field
rushes past the rotor poles so quickly that the rotor does not have a chance to
get started. In effect, the rotor is repelled first in one direction and then
the other. A synchronous motor in its purest form has no starting torque. It has
torque only when it is running at synchronous speed. A squirrel-cage type of
winding is added to the rotor of a synchronous motor to cause it to start. The squirrel
cage is shown as the outer part of the rotor in figure (2). It is so named
because it is shaped and looks something like a turnable squirrel cage. Simply,
the windings are heavy copper bars shorted together by copper
rings. A low voltage is induced in these shorted windings by the rotating
three-phase stator field. Because of the short circuit, a relatively large
current flows in the squirrel cage. This causes a magnetic field that interacts
with the rotating field of the stator. Because of the interaction, the rotor begins
to turn, following the stator field; the motor starts. We will run into
squirrel cages again in other applications, where they will be covered in more
detail.
fig.(2) |
To start a practical
synchronous motor, the stator is energized, but the dc supply to the rotor
field is not energized. The squirrel-cage windings bring the rotor to near
synchronous speed. At that point, the dc field is energized. This locks the
rotor in step with the rotating stator field. Full torque is developed, and the
load is driven. A mechanical switching device that operates on centrifugal
force is often used to apply
dc to the rotor as
synchronous speed is reached. The practical synchronous motor has the
disadvantage of requiring a dc exciter voltage for the rotor. This voltage may
be obtained either externally or internally, depending on the design of the
motor.
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